Introduction to the RSC Advances themed collection Chemistry in Biorefineries

Professor Carlos Martín, Professor Alejandro Rodríguez and Professor Fabio Montagnaro introduce the RSC Advances themed collection Chemistry in Biorefineries.


Introduction
The biorenery concept, which takes traditional reneries as a starting point and adapts them to environmentally friendly processes based on bioresources as raw materials, has attracted signicant scientic interest during the last few years. 1 Bioreneries are a realistic alternative for producing the advanced biofuels, bio-based materials, and chemicals required in a post-petroleum scenario. 2he residual lignocellulosic biomass generated by agriculture, forestry, crop processing, and other industries is a major feedstock base for bioreneries.Biomass abundance, low cost, and composition provide the required raw materials for the sustainable development of society without depending on fossil-based resources. 3Setting up efficient bioreneries requires a deep understanding of the chemistry behind the biorening processes.This themed collection aims to deepen the current knowledge of chemistry in bioreneries.

This collection
The themed collection Chemistry in bio-reneries features 15 contributions, including 13 original research papers and 2 review articles.The contributions come from almost all the main geographical areas of the world, from North to South America, from Europe to Africa and Asia, and cover recent developments in the chemistry of lignocellulose components, methods for fractionation of lignocellulosic biomass, and chemical conversion processes occurring in bioreneries.
Biomass fractionation is a core step for valorisation of the main constituents following a complete biorenery approach. 4In this collection, three articles contribute to enhancing the understanding of biomass fractionation.Monção et al. report the fractionation of bres of the halophyte plant Salicornia dolichostachya by organosolv pretreatment (https://doi.org/10.1039/D2RA04432C).
By carefully controlling the process parameters, cellulose-rich pretreated solids were produced, and high removal of hemicelluloses and lignin were achieved.The obtained cellulose was completely hydrolysable, the lignin fraction had high purity, and the hemicelluloses were recovered as a separate product consisting mostly of oligosaccharides.Ovejero-Pérez et al.Hydrothermal pretreatment is an effective method for lignocellulose fractionation, 5 but it cannot avoid the formation of inhibitors of the enzymatic saccharication and the microbial fermentation, which are two major operations in biorening. 6 In a biorenery environment, lignin, which is the major aromatic constituent of lignocellulosic biomass, can be RSC Advances EDITORIAL valorised to aromatics, polymers, biofuels, and biomaterials. 7,8This collection features four contributions dealing with lignin characterisation and valorisation.Li et al. present an assessment of the opportunities and challenges of catechyl lignin (C-lignin), a recently discovered biopolymer, whose homogeneous linear structure facilitates chemical conversion and provides new valorisation perspectives (https://doi.org/10.1039/D3RA01546G).The review summarises the biosynthesis of C-lignin in plants, provides an overview on its isolation and on various depolymerisation approaches, and explores new application areas based on its unique structure.The advantages and drawbacks of different methods for C-lignin isolation are discussed, the potential of treatments with deep eutectic solvents is highlighted, and the reductive catalytic fractionation as an emerging technology for effective depolymerisation is addressed.
Lignin's versatile chemistry allows many reactions through its multiple functional groups. 9That enables addition of different functionalities, which provide specic properties that make it suitable for replacing fossil-based polymers.In a review on lignin applications, Ruwoldt et al. summarise the state of the art on the development of lignin-based functional surfaces, lms, and coatings, with a focus on the formulation and nal uses (https://doi.org/10.1039/D2RA08179B).The article discusses the potential of technical lignins, a currently under utilised by-product of pulping and biorenery processes, which has a huge potential for chemical modi-cation and upgrading to different material applications.
Although poplar is a hardwood tree of major importance for biorenery applications, 10 the structure of lignin from different organs has so far not been investigated to a comparable extent.Stem lignin has been well studied, while foliar lignin has been less well studied.In this collection, original research by Bryant et al. discloses new knowledge on the chemistry of poplar foliar lignin (https:// doi.org/10.1039/D3RA03142J).A set of 11 Populus trichocarpa foliage samples was characterised using advanced analytical techniques.Clear differences between foliage and stem tissues were revealed using advanced analytical techniques.Heteronuclear single-quantum coherence nuclear magnetic resonance and Fourier-transform infrared spectroscopy revealed high variability in lignin structure, while gas chromatography-mass spectrometry showed a high degree of metabolite abundance.
Another lignin-related contribution of interest is a solid-state chemical modication protocol without external gas supply nor liquid reactants, developed by Wurzer et al. to generate N-lignins (https://doi.org/10.1039/D3RA00691C).The new protocol allows the performance of the lignin modication in closed continuous reactor systems, and it is expected to widen the possibilities of using N-lignins as an organic fertiliser or soil amendment.
Spent coffee ground (SCG) is an agroindustrial waste with potential as feedstock for bioreneries. 11The controlled hydrolysis of galactoglucomannan, the main SCG carbohydrate, leads to the formation of mannooligosaccharides (MOS), which have health-promoting effects due to their prebiotic and antioxidant activity. 12Magengelele et al. reported MOS production from SCGs by alkaline pretreatment followed by hydrolysis with a Bacillus sp.derived endo-b-1,4mannanase (https://doi.org/10.1039/D2RA07605E).An in vitro evaluation of the product showed its prebiotic effect on benecial bacteria, e.g., Lactobacillus bulgaricus, Bacillus subtilis and Streptococcus thermophilus.Assays performed under simulated gastric conditions revealed that the product is suitable for oral administration.
The Guest Editors would like to thank all the experts that have authored the articles included in this themed collection.Their high-quality contributions provide highly valuable new insights that will be well appreciated by readers interested in the fascinating area of the chemistry of biorening processes.